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Halophilic Archaea (halophilic + archaea)

Distribution by Scientific Domains

Life Sciences	83%

Selected Abstracts

Halophilic archaea in the human intestinal mucosa

ENVIRONMENTAL MICROBIOLOGY, Issue 9 2010
Andrew P. A. Oxley
Summary The human gastrointestinal tract microbiota, despite its key roles in health and disease, remains a diverse, variable and poorly understood entity. Current surveys reveal a multitude of undefined bacterial taxa and a low diversity of methanogenic archaea. In an analysis of the microbiota in colonic mucosal biopsies from patients with inflammatory bowel disease we found 16S rDNA sequences representing a phylogenetically rich diversity of halophilic archaea from the Halobacteriaceae (haloarchaea), including novel phylotypes. As the human colon is not considered a salty environment and haloarchaea are described as extreme halophiles, we evaluated and further discarded the possibility that these sequences originated from pre-colonoscopy saline lavage solutions. Furthermore, aerobic enrichment cultures prepared from a patient biopsy at low salinity (2.5% NaCl) yielded haloarchaeal sequence types. Microscopic observation after fluorescence in situ hybridization provided evidence of the presence of viable archaeal cells in these cultures. These results prove the survival of haloarchaea in the digestive system and suggest that they may be members of the mucosal microbiota, even if present in low numbers in comparison with methanogenic archaea. Investigation of a potential physiological basis of this association may lead to new insights into gastrointestinal health and disease. [source]

Characterization of the microbial diversity in a permafrost sample from the Canadian high Arctic using culture-dependent and culture-independent methods

FEMS MICROBIOLOGY ECOLOGY, Issue 2 2007
Blaire Steven
Abstract A combination of culture-dependent and culture-independent methodologies (Bacteria and Archaea 16S rRNA gene clone library analyses) was used to determine the microbial diversity present within a geographically distinct high Arctic permafrost sample. Culturable Bacteria isolates, identified by 16S rRNA gene sequencing, belonged to the phyla Firmicutes, Actinobacteria and Proteobacteria with spore-forming Firmicutes being the most abundant; the majority of the isolates (19/23) were psychrotolerant, some (11/23) were halotolerant, and three isolates grew at ,5°C. A Bacteria 16S rRNA gene library containing 101 clones was composed of 42 phylotypes related to diverse phylogenetic groups including the Actinobacteria, Proteobacteria, Firmicutes, Cytophaga , Flavobacteria , Bacteroides, Planctomyces and Gemmatimonadetes; the bacterial 16S rRNA gene phylotypes were dominated by Actinobacteria- and Proteobacteria -related sequences. An Archaea 16S rRNA gene clone library containing 56 clones was made up of 11 phylotypes and contained sequences related to both of the major Archaea domains (Euryarchaeota and Crenarchaeota); the majority of sequences in the Archaea library were related to halophilic Archaea. Characterization of the microbial diversity existing within permafrost environments is important as it will lead to a better understanding of how microorganisms function and survive in such extreme cryoenvironments. [source]

Anaerobiosis inhibits gas vesicle formation in halophilic Archaea

MOLECULAR MICROBIOLOGY, Issue 1 2009
Torsten Hechler
Summary The effect of anaerobiosis on the gas vesicle formation was investigated in three Halobacterium salinarum strains, Haloferax mediterranei and in Haloferax volcanii transformants. All these strains significantly reduced gas vesicle formation or lacked these structures under anoxic conditions. When grown by arginine fermentation, Hbt. salinarum PHH4 lacked gas vesicles, whereas Hbt. salinarum PHH1 and NRC-1 contained 5,20 small gas vesicles arranged in two to three aggregates per cell instead of the 30,80 gas vesicles present under oxic conditions. The enlargement presumably stopped due to a depletion of Gvp proteins. Also Hfx. mediterranei and Hfx. volcanii transformants lacked gas vesicles under anoxic growth and yielded a 10-fold reduced gvp transcription. Even the gas vesicle-overproducing ,D transformants did not form gas vesicles under anoxic conditions, demonstrating that the repressing protein GvpD was not involved. The presence of large amounts of GvpA implied that the assembly of the gas vesicles was inhibited. When Hbt. salinarum PHH1 and NRC-1 were grown with dimethyl sulphoxide or trimethylamine N -oxid under anoxic conditions the number but not the size of gas vesicles was reduced. This was in contrast to the previously reported overproduction of gas vesicles in NRC-1 that turned out to depend on the citrate-containing medium used for growth. [source]

Halophilic archaea in the human intestinal mucosa

Membrane binding of SRP pathway components in the halophilic archaea Haloferax volcanii

FEBS JOURNAL, Issue 7 2004
Tovit Lichi
Across evolution, the signal recognition particle pathway targets extra-cytoplasmic proteins to membranous translocation sites. Whereas the pathway has been extensively studied in Eukarya and Bacteria, little is known of this system in Archaea. In the following, membrane association of FtsY, the prokaryal signal recognition particle receptor, and SRP54, a central component of the signal recognition particle, was addressed in the halophilic archaea Haloferax volcanii. Purified H. volcanii FtsY, the FtsY C-terminal GTP-binding domain (NG domain) or SRP54, were combined separately or in different combinations with H. volcanii inverted membrane vesicles and examined by gradient floatation to differentiate between soluble and membrane-bound protein. Such studies revealed that both FtsY and the FtsY NG domain bound to H. volcanii vesicles in a manner unaffected by proteolytic pretreatment of the membranes, implying that in Archaea, FtsY association is mediated through the membrane lipids. Indeed, membrane association of FtsY was also detected in intact H. volcanii cells. The contribution of the NG domain to FtsY binding in halophilic archaea may be considerable, given the low number of basic charges found at the start of the N-terminal acidic domain of haloarchaeal FtsY proteins (the region of the protein thought to mediate FtsY,membrane association in Bacteria). Moreover, FtsY, but not the NG domain, was shown to mediate membrane association of H. volcanii SRP54, a protein that did not otherwise interact with the membrane. [source]

Signal Transfer in Haloarchaeal Sensory Rhodopsin, Transducer Complexes,

PHOTOCHEMISTRY & PHOTOBIOLOGY, Issue 4 2008
Jun Sasaki
Membrane-inserted complexes consisting of two photochemically reactive sensory rhodopsin (SR) subunits flanking a homodimer of a transducing protein subunit (Htr) are used by halophilic archaea for sensing light gradients to modulate their swimming behavior (phototaxis). The SR,Htr complexes extend into the cytoplasm where the Htr subunits bind a his-kinase that controls a phosphorylation system that regulates the flagellar motors. This review focuses on current progress primarily on the mechanism of signal relay within the SRII,HtrII complexes from Natronomonas pharaonis and Halobacterium salinarum. The recent elucidation of a photoactive site steric trigger crucial for signal relay, advances in understanding the role of proton transfer from the chromophore to the protein in SRII activation, and the localization of signal relay to the membrane-embedded portion of the SRII,HtrII interface, are beginning to produce a clear picture of the signal transfer process. The SR,Htr complexes offer unprecedented opportunities to resolve first examples of the chemistry of signal relay between membrane proteins at the atomic level, which would provide a major contribution to the general understanding of dynamic interactions between integral membrane proteins. [source]